Notice: Trying to get property 'display_name' of non-object in /var/www/html/wp-content/plugins/wordpress-seo/src/generators/schema/article.php on line 52
keyboard_arrow_uptop

If you remember, last time out we looked at that sabermetric darling, the strikeout, noting the steady increase in strikeout rate that we’ve seen over the past four decades. In part two, we’ll look at a couple of factors that affect pitcher’s strikeout rates.

Ballpark Effects

One factor sometimes ignored when considering a pitcher’s (or hitter’s) strikeout rate is the effect that the various major league ballparks can have on the strikeout rates of the hurlers who pitch in them. We’re familiar with the concept of a ballpark effect when we talk about offense: the potential home run-boosting effect caused by close outfield fences, or of the possible hit-suppressing effect of a large area of foul ground on the field of play. These have an effect on batted balls that we can understand intuitively. Less intuitive is that the ballpark can also increase or reduce the rate of non-contact results like walks and strikeouts.

Why does this happen? Much of the ballpark effect on strikeouts is attributed to visibility factors. First, no two ballparks have an identical “batter’s eye,” the background against which the batter sees the pitch after it leaves the pitcher’s hand. There are other factors, however, like the late afternoon shadows at ballparks like Wrigley Field, which are also thought to have an effect on how well the batter sees the pitch, and accordingly how likely the hitter is to get rung up on strikes. High altitude makes it more difficult to throw breaking pitches, a factor which is thought to be responsible for the extreme strikeout-suppressing qualities of Colorado’s Coors Field. It is possible that other elements, such as how an individual park’s groundskeepers maintain the pitching mound, could add or detract from a pitcher’s effectiveness, including their strikeout rate.

Here’s a list of the ballpark strikeout factor for each team’s home field. The strikeout factor is arranged so that 1000 is a perfect strikeout-neutral ballpark; higher numbers mean the park increases strikeouts, and lower numbers mean that the park suppresses strikeouts.


Team Park                    Factor  Team Park                   Factor
SEA  Safeco Field              1047  CIN  Great American Ballpark  1002
FLO  Joe Robbie Stadium        1040  LAA  Anaheim Stadium           998
MIL  Miller Park               1035  NYA  Yankee Stadium II         997
SDN  Petco Park                1034  NYN  Shea Stadium              993
MIN  Metrodome                 1026  PHI  Citizens Bank Park        988
CHN  Wrigley Field             1017  TEX  Ballpark at Arlington     987
TBA  Tropicana Field           1015  SFN  PacBell Park              987
CLE  Jacobs Field              1014  SLN  New Busch Stadium         985
LAN  Dodger Stadium            1012  ARI  Bank One Ballpark         978
TOR  Skydome                   1011  KCA  Kauffmann Stadium (04-06) 978
ATL  Turner Field              1008  OAK  Oakland Coliseum          975
WAS  RFK Stadium  (Nationals)  1008  PIT  PNC Park                  974
BOS  Fenway Park               1004  DET  Comerica Park (03-06)     973
CHA  U.S. Cellular (01-06)     1003  BAL  Camden Yards              972
HOU  Minute Maid Park          1003  COL  Coors Field               937

Pitcher Pacing

Reader J.D. chimed in with this comment after my first strikeout article:

I liked your article on strikeout rates, but I think that in addition to adjusting for eras there is another bias that favors modern pitchers. Today’s pitchers get pulled in the sixth inning at about 110 pitches, no matter how they’re feeling. Naturally they will have higher strikeout rates than earlier pitchers who had labor through nine innings, seeing their strikeout rates diminish due to fatigue in later innings. I don’t know how you can adjust for this, but I think that it does benefit modern pitchers beyond just the overall strikeout rates of the modern era. I think Sandy Koufax averaging 10 strikeouts while also averaging close to nine innings is just good, if not better, than Kerry Wood averaging eight strikeouts in seven innings. Like you said right off the top of the article, strikeouts per nine innings is antiquated since nobody goes nine innings anymore.

Now, underlying J.D.’s question is an assumption that strikeout rate goes down as pitchers throw more innings/pitches. This was mentioned in a number of letters I received, with reader D.K. asking point-blank, ” Do starting pitchers have more strikeouts when their pitch counts are lower or higher?”

This seemed like a very good question, so I did what any reasonable person would do: I asked someone much smarter than me-in this case, the indefatigable Bil Burke-to show me some data.

Strikeout Rate Per Number of Pitches Thrown 2000-2007
            Overall    Relievers             Starters
Pitches     SO Rate      PA       SO Rate      PA      SO Rate
1-25        17.41%     412,553    18.41%     225,961   15.59%
26-50       17.10%      65,072    18.90%     243,527   16.62%
51-75       15.73%       6,906    16.38%     238,220   15.71%
76-100      14.97%         789    17.74%     186,743   14.96%
101-125     17.61%          47    25.53%      53,107   17.60%
126-150     21.97%           0     N/A         1,502   21.97%
151+        33.33%           0     N/A             6   33.33%

These numbers are based on pitcher’s individual pitch counts, tied to the number of pitches thrown at the end of each plate appearance. What the numbers show is a clear downward trend in strikeout rate after the first 50 pitches, presumably as pitchers tire. After 100 pitches, the strikeout rates go up again, as the pitchers to surpass the 100-pitch barrier are generally pitching well, but also get pulled promptly if they run into any trouble.

There’s also an issue of selection bias, where better pitchers with good strikeout rates are allowed to pitch deeper into games. If you want to get a pretty good idea of the quality of the pitchers who are going over that 100-pitch mark, you can look at the Pitcher Abuse Point report for the last eight seasons, where pitcher’s starts are categorized according to the number of pitches thrown per start. When you look at Categories 4 and 5, which represent pitch counts of 122 and higher, you can see that the pitchers who allowed to pitch that deep into the game are a fairly distinguished group-you see a lot of Randy Johnson and Curt Schilling on those lists-so it makes sense that the strikeout rates remain higher than average in the last three categories.

Getting back to J.D.’s original question- Sandy Koufax versus Kerry Wood, and the question of whether or not the historical rate adjustments done in the Davenport Translations capture the differences between the eras in which they pitched-we see that J.D. might have a point. Quicker hooks and attention to pitch counts for modern-day starting pitchers mean that they can pitch in an all-out fashion, knowing that they’re not expected to complete the game, while pitchers in Koufax’s era are generally considered to have paced themselves in order to go the distance.

But a closer look at the data above indicates that perhaps the increases in strikeout rates of the 21st century aren’t being driven by the starting pitchers like Kerry Wood, but rather by relievers. The starter’s strikeout rate from 2000-2007 is 15.88 percent; for relievers, it’s 18.44 percent. These high-strikeout relievers are pitching a greater percentage of team innings than they did in Koufax’s time. For example, in 1961 relievers pitched 28.5 percent of their team’s innings, by 2001, the reliever’s share of innings had risen to 33.4 percent. Since the Davenport Translations are based on league strikeout rates, it’s possible that a modern starter would be underrated, because relievers are inflating the league strikeout rate.

We’ll continue this discussion in part three of the Non-Contact series, where we’ll talk some more about strikeouts, and add hitters to the mix.

Further Reading:

Dayn Perry, “Can of Corn-Putting the Park Back in Park Factors”: An introduction to the concept of component park factors.

James Click, “Crooked Numbers-Ballpark Effects on Pitcher Types”: Looks at the effect of the league-wide ballpark factor on the performance-including strikeout rates-of fly ball and ground ball pitchers.

Nate Silver, “Lies, Damned Lies-What to Do With Papelbon”: A study of the effects of converting starting pitchers to relief, with the finding that starters so converted will generally have significantly higher strikeout rates than they would as relievers.

Thank you for reading

This is a free article. If you enjoyed it, consider subscribing to Baseball Prospectus. Subscriptions support ongoing public baseball research and analysis in an increasingly proprietary environment.

Subscribe now
You need to be logged in to comment. Login or Subscribe